The present invention relates to a method for reducing a level of acrylamide in a heat-treated, processed food, a production method for producing a heat-treated, processed food with a reduced level of acrylamide, and an ingredient for suppressing acrylamide formation.
It is known that high levels of acrylamide is found in carbohydrate-rich food products that have been processed at a temperature of 120° C. or higher such as potato chips, fried potatoes, biscuits, etc. It is also known that acrylamide is formed when asparagine, one of the major amino acids found in potatoes and cereals, reacts with reducing sugar through Maillard reaction.
Acrylamide belongs to the group of the carcinogenic compounds, thus lowering the level of acrylamide in the processed foods is highly desirable.
There have been a number of reports on methods for suppressing acrylamide formation in the production process of the processed foods, such as methods for enzymatically degrading asparagine, a precursor for acrylamide (Patent Documents 1 and 2, etc.) and methods for suppressing acrylamide formation by adding various ingredients (Patent Documents 3-8).
However, no method is capable of reducing the level of acrylamide sufficiently. Furthermore, when some kinds of enzyme are added to reduce the level of acrylamide in foods, the safety of the by-product produced through the enzymatic reactions, as well as the ingredients themselves to be added, should be carefully considered.
An object of the present invention is to provide a method for reducing a level of acrylamide in a heat-treated, processed food using a highly safe and effective ingredient for suppressing acrylamide formation.
The present inventors examined plant-derived ingredients and found that the level of acrylamide in heat-treated, processed foods is able to be significantly reduced by adding dihydroquercetin that is contained in a plant such as Siberian Larch to carbohydrate-containing processed food ingredients or allowing the dihydroquercetin to permeate the carbohydrate-containing processed food ingredients, to thereby complete the present invention.
The present invention provides a method for reducing a level of acrylamide in a processed food, including adding dihydroquercetin to a carbohydrate-containing processed food ingredient or allowing dihydroquercetin to permeate the carbohydrate-containing processed food ingredient prior to or during a heat-treating process.
The present invention also provides a production method for producing a processed food with a reduced level of acrylamide, including adding dihydroquercetin to a carbohydrate-containing processed food ingredient or allowing dihydroquercetin to permeate the carbohydrate-containing processed food ingredient prior to or during a heat-treating process.
In addition, the present invention provides an ingredient for suppressing acrylamide formation in a processed food, containing dihydroquercetin or a plant extract containing dihydroquercetin.
The present invention permits the production of the processed foods with a reduced level of acrylamide in a safe and convenient way.
The method for reducing the level of acrylamide and the production method for producing the processed food of the present invention are characterized in that dihydroquercetin is used as an ingredient for suppressing acrylamide formation. Dihydroquercetin is a kind of flavonoid with the structure shown below.
The Dihydroquercetin can be synthesized chemically, but plant extracts containing dihydroquercetin can also be used. The plants containing dihydroquercetin include, for example, those that belong to the family Pinaceae. Among them, the plants belonging to the genus Pinus or Larix kaempferi are preferable. More specifically, Siberian Larch (Larix sibirica), Dahurian Larch (Larix dahurica), Siberian Pine (Pinus sibirica), Scots Pine (Pinus sylvestris), Jezo Spruce (Picea ajanensis), etc. are preferable for the present invention.
The locus for extraction from the aforementioned plants may contain cortex and xylem, but the xylem containing cambiums is specifically preferred. The xylem from a plant belonging to the family Pinaceae such as Siberian Larch is rich in dihydroquercetin, therefore the xylem containing cambiums is the most preferred locus for extraction.
For the present invention, extraction methods using organic solvents, water, or mixtures thereof are preferred. Water, ethanol, ethyl acetate, acetone, or mixtures thereof can be used as solvents in the present invention, however, for safety reasons, etc, water, ethanol or a water/ethanol mixture is more preferred. More specifically, for example, it is preferable to extract chopped xylem or xylem containing cambiums with water, ethanol or a water/ethanol mixture in a condition of high temperature (i.e. 50 to 100° C.). If necessary, the extract can be further purified by condensation, distillation, re-crystallization or other methods.
When using plant extracts containing dihydroquercetin, the concentration of dihydroquercetin in the extracts is preferably 50% (w/w) or higher, more preferably 60% (w/w) or higher, and further more preferably 80% (w/w) or higher. The upper limit of the concentration of dihydroquercetin in the extracts is 100% (w/w).
The processed food ingredients to be used in the present invention are ingredients containing carbohydrates such as starch that possibly form acrylamide during the heat-treating process of the processed food ingredients. More specifically, the present invention applies to the processed food ingredients containing carbohydrates, such as glucose and fructose, in combination with asparagine or peptides containing asparagine as a constituent amino acid.
Such processed food ingredients include asparagine-rich food materials such as potatoes, peas, black peppers, white peppers, burdock roots, kidney beans, turmeric, pumpkins, sweet potatoes, corns, wheat, rice and food materials derived from these. Such food materials include, for example, dehydrated and powdered forms thereof.
The method of the present invention is characterized in that dihydroquercetin is added to the aforementioned processed food ingredients or allowed to permeate the aforementioned processed food ingredients prior to or during the heat-treating process of the processed food ingredients.
In order to reduce acrylamide levels without affecting color, taste and flavor of the processed food products, the amount of dihydroquercetin added to the processed food ingredients is preferably 0.06 to 6% (w/w), more preferably 0.06 to 2% (w/w), further more preferably 0.06 to 0.6 parts by weight, and most preferably 0.06 to 0.3 parts by weight based on 100 parts by weight of the processed food ingredients on dry weight basis. By adding dihydroquercetin at the concentration, the level of acrylamide can be sufficiently reduced without affecting the color, taste, and flavor of the processed food products. This addition amount is based on the weight of dihydroquercetin and in the case of using the plant extract, the amount may be adjusted according to the dihydroquercetin content in the plant extract.
For addition or permeation of dihydroquercetin, powdered form of dihydroquercetin is acceptable as it can be uniformly dispersed and dissolved by direct addition to the processed food ingredients when the processed food ingredients are in liquid or paste form. However, when the processed food ingredients themselves are in powder or solid form, it is preferable that dihydroquercetin be dissolved in or mixed with water or ethanol and then added to the processed food ingredients. For permeation of dihydroquercetin, when frying, boiling, etc., it is preferable that dihydroquercetin be added into the cooking liquids or cooking oil, and then allowed to permeate the processed food ingredients during the heat-treating process.
When frying or boiling, it is difficult to determine the permeation amount of dihydroquercetin in the processed food ingredients, therefore it is preferable that dihydroquercetin be added into cooking liquids or cooking oil at a concentration of 0.06 to 6% (w/v), more preferably 0.06 to 2% (w/v), further more preferably 0.06 to 0.6% (w/v), and most preferably 0.06 to 0.3% (w/v) prior to the heat-treaing process. Since the solubility of dihydroquercetin in ordinary oils is relatively low, it is preferable that dihydroquercetin be dissolved in a small amount of pre-heated cooking oil, or in cooking oil containing a surfactant, a monoacyl glycerol or a diacyl glycerol. Also, dihydroquercetin can be dispersed in cooking oil by ultrasonication. The processed food ingredients can be fried in oil, into which dihydroquercetin was added, dispersed or preferably dissolved, and this method can be applied to the frying of sliced raw potatoes.
In the method for reducing the level of acrylamide and the production method for producing the processed food of the present invention, acrylamide formation is suppressed even in the heat-treating process by adding dihydroquercetin to the processed food ingredients or allowing dihydroquercetin to permeate the processed food ingredients prior to or during the heat-treating process. A large amount of acrylamide is formed when the ingredients are heated at 120° C. or higher, therefore the present invention can be applied to the production of processed foods that requires a heat-treating process such as frying, baking, roasting and boiling at 120° C. or higher.
Processed foods to which the method of the present invention can be applied include potato chips, fried potatoes, popcorns, snack foods, rice crackers, cookies, crackers, biscuits, fried dough-cake, instant noodles, instant wanton and cereals.
According to the method of the present invention, the acrylamide content in the processed foods produced is able to be reduced to less than 70%, preferably to less than 60%, more preferably to less than 30%, and most preferably to less than 15% of that found in the processed foods produced by conventional heat-treating methods.
Following examples will be used to provide detailed illustrations of the present invention, but the present invention is not limited to these examples.
Using a Siberian Larch extract containing 60% of dihydroquercetin, the effect of reducing the level of acrylamide in potato chips was studied. Potato flakes were prepared as follows. Potatoes were first boiled at 70° C. and cooled. Next, they were braised, then mashed, and the mashed dough was dried with hot air until the moisture content was reduced to from 4 to 9% and then ground. The Siberian Larch extract was pre-dissolved in 3 ml ethanol and mixed with water, then the mixture was added to the ground potato flake dough. Potato chips were then produced by frying the dough at the conditions indicated in Table 1. The level of acrylamide found in these potato chips was measured by GC-MS. Table 1 shows the results, and
*1The added amount was determined based on dry weight of the potato flake ingredients.
*2The extract contains 60% of dihydroquercetin.
When dihydroquercetin was added at a concentration of 0.06 to 0.6%, the level of acrylamide in potato chips was reduced by about 30 to 70%, notably, when dihydroquercetin was added at a concentration of 0.6%, the level was reduced by about 70% (Table 1). Furthermore, the addition of dihydroquercetin did not affect the color, taste and flavor of the potato chips (
A Siberian Larch extract containing 60% of dihydroquercetin was dissolved into a small amount of oil heated to 70° C., then the dihydroquercetin-containing oil was added to cooking oil. Potato chips were produced by frying sliced raw potatoes in the cooking oil. The level of acrylamide found in these potato chips was measured by GC-MS. Table 2 shows the results, and
The results show that the acrylamide level was significantly reduced in potato chips fried in cooking oil containing 0.06 to 0.3% (w/v) of dihydroquercetin. Furthermore, frying in cooking oil containing dihydroquercetin did not affect the color, taste and flavor of the potato chips (
Number | Date | Country | Kind |
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2010-145115 | Jun 2010 | JP | national |
2011-009931 | Jan 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP11/64152 | 6/21/2011 | WO | 00 | 12/19/2012 |